flightgear/src/FDM/UFO.cxx

// UFO.cxx -- interface to the "UFO" flight model
//
// Written by Curtis Olson, started October 1999.
// Slightly modified from MagicCarpet.cxx by Jonathan Polley, April 2002
//
// Copyright (C) 1999-2002  Curtis L. Olson  - curt@flightgear.org
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License as
// published by the Free Software Foundation; either version 2 of the
// License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful, but
// WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
// General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
//


#include <simgear/math/sg_geodesy.hxx>
#include <simgear/math/point3d.hxx>
#include <simgear/math/polar3d.hxx>

#include <Controls/controls.hxx>
#include <Main/globals.hxx>
#include <Main/fg_props.hxx>

#include "UFO.hxx"


FGUFO::FGUFO( double dt ) {
    set_delta_t( dt );
}


FGUFO::~FGUFO() {
}


// Initialize the UFO flight model, dt is the time increment
// for each subsequent iteration through the EOM
void FGUFO::init() {
    common_init();
}


// Run an iteration of the EOM (equations of motion)
void FGUFO::update( int multiloop ) {
    // cout << "FGLaRCsim::update()" << endl;

    double time_step = get_delta_t() * multiloop;

    // read the throttle
    double Throttle = globals->get_controls()->get_throttle( 0 );

    // read the state of the control surfaces
    double Aileron  = globals->get_controls()->get_aileron();
    double Elevator = globals->get_controls()->get_elevator();

    // the velocity of the aircraft
    double velocity = Throttle * 2000; // meters/sec

    double old_pitch = get_Theta();
    double pitch_rate = SGD_PI_4; // assume I will be pitching up
    double target_pitch = -Elevator * SGD_PI_2;

    // if I am pitching down
    if (old_pitch > target_pitch)
        // set the pitch rate to negative (down)
        pitch_rate *= -1;

    double pitch = old_pitch + (pitch_rate * time_step);

    // if I am pitching up
    if (pitch_rate > 0.0)
    {
        // clip the pitch at the limit
        if ( pitch > target_pitch)
        {
            pitch = target_pitch;
        }
    }
    // if I am pitching down
    else if (pitch_rate < 0.0)
    {
        // clip the pitch at the limit
        if ( pitch < target_pitch)
        {
            pitch = target_pitch;
        }
    }

    double old_roll     = get_Phi();
    double roll_rate    = SGD_PI_4;
    double target_roll  = Aileron * SGD_PI_2;

    if (old_roll > target_roll)
        roll_rate *= -1;
    
    double roll = old_roll + (roll_rate * time_step);

    // if I am rolling CW
    if (roll_rate > 0.0)
    {
        // clip the roll at the limit
        if ( roll > target_roll)
        {
            roll = target_roll;
        }
    }
    // if I am rolling CCW
    else if (roll_rate < 0.0)
    {
        // clip the roll at the limit
        if ( roll < target_roll)
        {
            roll = target_roll;
        }
    }

    // the vertical speed of the aircraft
    double real_climb_rate = sin (pitch) * SG_METER_TO_FEET * velocity; // feet/sec
    _set_Climb_Rate( -Elevator * 10.0 );
    double climb = real_climb_rate * time_step;

    // the lateral speed of the aircraft
    double speed = cos (pitch) * velocity; // meters/sec
    double dist = speed * time_step;
    double kts = velocity * SG_METER_TO_NM * 3600.0;
    _set_V_equiv_kts( kts );
    _set_V_calibrated_kts( kts );
    _set_V_ground_speed( kts );

    // angle of turn
    double turn_rate = sin(roll) * SGD_PI_4; // radians/sec
    double turn = turn_rate * time_step;

    // update (lon/lat) position
    double lat2, lon2, az2;
    if ( speed > SG_EPSILON ) {
	geo_direct_wgs_84 ( get_Altitude(),
			    get_Latitude() * SGD_RADIANS_TO_DEGREES,
			    get_Longitude() * SGD_RADIANS_TO_DEGREES,
			    get_Psi() * SGD_RADIANS_TO_DEGREES,
			    dist, &lat2, &lon2, &az2 );

	_set_Longitude( lon2 * SGD_DEGREES_TO_RADIANS );
	_set_Latitude( lat2 * SGD_DEGREES_TO_RADIANS );
    }

    // cout << "lon error = " << fabs(end.x()*SGD_RADIANS_TO_DEGREES - lon2)
    //      << "  lat error = " << fabs(end.y()*SGD_RADIANS_TO_DEGREES - lat2)
    //      << endl;

    double sl_radius, lat_geoc;
    sgGeodToGeoc( get_Latitude(), get_Altitude(), &sl_radius, &lat_geoc );

    // update euler angles
    _set_Euler_Angles( roll, pitch,
                       fmod(get_Psi() + turn, SGD_2PI) );
    _set_Euler_Rates(0,0,0);

    _set_Geocentric_Position( lat_geoc, get_Longitude(), 
			     sl_radius + get_Altitude() + climb );
    // cout << "sea level radius (ft) = " << sl_radius << endl;
    // cout << "(setto) sea level radius (ft) = " << get_Sea_level_radius() << endl;
    _set_Sea_level_radius( sl_radius * SG_METER_TO_FEET);
    _set_Altitude( get_Altitude() + climb );
}
UFO FDM patches from Jonathan Polley: I have finished working the bugs out of my "Enhanced" version of the Magic Carpet FDM. The UFO FDM works the same as the Magic Carpet with the following exceptions: The aircraft's pitch is determined by the Elevator setting (with a pitch rate of 45 degrees per second). Climb is forward velocity * sin(pitch) Speed is forward velocity * soc(pitch) Roll is tied to the aileron (again, with a roll rate of 45 degrees per second) Turn rate is sin(roll) * 45 degrees. Yes, this does mean that turning is quite a bit more sluggish than climbing. If you are wondering why a UFO FDM, it is because it's best that I not replace the existing magic carpet and this FDM does behave like a UFO (it hovers, can spin and pitch while hovering, and does not obey the laws of physics ;) 2002-04-25 16:23:16 +00:00			`// UFO.cxx -- interface to the "UFO" flight model`
			`//`
			`// Written by Curtis Olson, started October 1999.`
			`// Slightly modified from MagicCarpet.cxx by Jonathan Polley, April 2002`
			`//`
			`// Copyright (C) 1999-2002 Curtis L. Olson - curt@flightgear.org`
			`//`
			`// This program is free software; you can redistribute it and/or`
			`// modify it under the terms of the GNU General Public License as`
			`// published by the Free Software Foundation; either version 2 of the`
			`// License, or (at your option) any later version.`
			`//`
			`// This program is distributed in the hope that it will be useful, but`
			`// WITHOUT ANY WARRANTY; without even the implied warranty of`
			`// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
			`// General Public License for more details.`
			`//`
			`// You should have received a copy of the GNU General Public License`
			`// along with this program; if not, write to the Free Software`
			`// Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.`
			`//`


			`#include <simgear/math/sg_geodesy.hxx>`
			`#include <simgear/math/point3d.hxx>`
			`#include <simgear/math/polar3d.hxx>`

			`#include <Controls/controls.hxx>`
			`#include <Main/globals.hxx>`
			`#include <Main/fg_props.hxx>`

			`#include "UFO.hxx"`


			`FGUFO::FGUFO( double dt ) {`
			`set_delta_t( dt );`
			`}`


			`FGUFO::~FGUFO() {`
			`}`


			`// Initialize the UFO flight model, dt is the time increment`
			`// for each subsequent iteration through the EOM`
			`void FGUFO::init() {`
			`common_init();`
			`}`


			`// Run an iteration of the EOM (equations of motion)`
			`void FGUFO::update( int multiloop ) {`
			`// cout << "FGLaRCsim::update()" << endl;`

			`double time_step = get_delta_t() * multiloop;`

			`// read the throttle`
			`double Throttle = globals->get_controls()->get_throttle( 0 );`

			`// read the state of the control surfaces`
			`double Aileron = globals->get_controls()->get_aileron();`
			`double Elevator = globals->get_controls()->get_elevator();`

			`// the velocity of the aircraft`
			`double velocity = Throttle * 2000; // meters/sec`

			`double old_pitch = get_Theta();`
			`double pitch_rate = SGD_PI_4; // assume I will be pitching up`
			`double target_pitch = -Elevator * SGD_PI_2;`

			`// if I am pitching down`
			`if (old_pitch > target_pitch)`
			`// set the pitch rate to negative (down)`
			`pitch_rate *= -1;`

			`double pitch = old_pitch + (pitch_rate * time_step);`

			`// if I am pitching up`
			`if (pitch_rate > 0.0)`
			`{`
			`// clip the pitch at the limit`
			`if ( pitch > target_pitch)`
			`{`
			`pitch = target_pitch;`
			`}`
			`}`
			`// if I am pitching down`
			`else if (pitch_rate < 0.0)`
			`{`
			`// clip the pitch at the limit`
			`if ( pitch < target_pitch)`
			`{`
			`pitch = target_pitch;`
			`}`
			`}`

			`double old_roll = get_Phi();`
			`double roll_rate = SGD_PI_4;`
			`double target_roll = Aileron * SGD_PI_2;`

			`if (old_roll > target_roll)`
			`roll_rate *= -1;`

			`double roll = old_roll + (roll_rate * time_step);`

			`// if I am rolling CW`
			`if (roll_rate > 0.0)`
			`{`
			`// clip the roll at the limit`
			`if ( roll > target_roll)`
			`{`
			`roll = target_roll;`
			`}`
			`}`
			`// if I am rolling CCW`
			`else if (roll_rate < 0.0)`
			`{`
			`// clip the roll at the limit`
			`if ( roll < target_roll)`
			`{`
			`roll = target_roll;`
			`}`
			`}`

			`// the vertical speed of the aircraft`
			`double real_climb_rate = sin (pitch) * SG_METER_TO_FEET * velocity; // feet/sec`
			`_set_Climb_Rate( -Elevator * 10.0 );`
			`double climb = real_climb_rate * time_step;`

			`// the lateral speed of the aircraft`
			`double speed = cos (pitch) * velocity; // meters/sec`
			`double dist = speed * time_step;`
			`double kts = velocity * SG_METER_TO_NM * 3600.0;`
			`_set_V_equiv_kts( kts );`
			`_set_V_calibrated_kts( kts );`
			`_set_V_ground_speed( kts );`

			`// angle of turn`
			`double turn_rate = sin(roll) * SGD_PI_4; // radians/sec`
			`double turn = turn_rate * time_step;`

			`// update (lon/lat) position`
			`double lat2, lon2, az2;`
			`if ( speed > SG_EPSILON ) {`
			`geo_direct_wgs_84 ( get_Altitude(),`
			`get_Latitude() * SGD_RADIANS_TO_DEGREES,`
			`get_Longitude() * SGD_RADIANS_TO_DEGREES,`
			`get_Psi() * SGD_RADIANS_TO_DEGREES,`
			`dist, &lat2, &lon2, &az2 );`

			`_set_Longitude( lon2 * SGD_DEGREES_TO_RADIANS );`
			`_set_Latitude( lat2 * SGD_DEGREES_TO_RADIANS );`
			`}`

			`// cout << "lon error = " << fabs(end.x()*SGD_RADIANS_TO_DEGREES - lon2)`
			`// << " lat error = " << fabs(end.y()*SGD_RADIANS_TO_DEGREES - lat2)`
			`// << endl;`

			`double sl_radius, lat_geoc;`
			`sgGeodToGeoc( get_Latitude(), get_Altitude(), &sl_radius, &lat_geoc );`

			`// update euler angles`
			`_set_Euler_Angles( roll, pitch,`
			`fmod(get_Psi() + turn, SGD_2PI) );`
			`_set_Euler_Rates(0,0,0);`

			`_set_Geocentric_Position( lat_geoc, get_Longitude(),`
			`sl_radius + get_Altitude() + climb );`
			`// cout << "sea level radius (ft) = " << sl_radius << endl;`
			`// cout << "(setto) sea level radius (ft) = " << get_Sea_level_radius() << endl;`
			`_set_Sea_level_radius( sl_radius * SG_METER_TO_FEET);`
			`_set_Altitude( get_Altitude() + climb );`
			`}`